Disaggregation and cloudification of metropolitan area networks: enabling technologies and impact on architecture, cost, and power consumption [Invited]

Marco Quagliotti; Laura Serra; Annachiara Pagano; Panos Groumas; Paraskevas Bakopoulos; Hercules Avramopoulos

doi:10.1364/JOCN.450822

Journal of Optical Communications and Networking
Vol. 14,
Issue 6,
pp. C38-C49
(2022)
•https://doi.org/10.1364/JOCN.450822

Disaggregation and cloudification of metropolitan area networks: enabling technologies and impact on architecture, cost, and power consumption [Invited]

Marco Quagliotti, Laura Serra, Annachiara Pagano, Panos Groumas, Paraskevas Bakopoulos, and Hercules Avramopoulos

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Marco Quagliotti, Laura Serra, Annachiara Pagano, Panos Groumas, Paraskevas Bakopoulos, and Hercules Avramopoulos, "Disaggregation and cloudification of metropolitan area networks: enabling technologies and impact on architecture, cost, and power consumption [Invited]," J. Opt. Commun. Netw. 14, C38-C49 (2022)

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About this Article
History
- Original Manuscript: December 15, 2021
- Revised Manuscript: February 28, 2022
- Manuscript Accepted: March 4, 2022
- Published: April 12, 2022
Virtual Issues
Journal of Optical Communications and Networking ECOC 2021 (2022)

Abstract

The deployment of the new 5G system and ultra-broadband access networks, on one side, and the advent of network disaggregation and cloudification paradigms, on the other, are producing disruptive changes in metropolitan area networks (MANs). The new central offices will be more like small data centers than traditional Telco-type central offices. The presence of general-purpose servers, in partial or total replacement of specialized equipment or cards, and also hosting new functions and services, significantly changes the way the central office is organized and how the equipment internetworks. After having defined a reference architecture named cloudified-MAN, the paper briefly introduces the enabling technologies that include information technology (IT) systems, packet switches, and optical equipment. A disaggregated model is applied to all layers and systems. In the optics field, special insight on high data rate (up to 1.6 Tb/s) transceiver technology developed by the TERIPHIC project is provided as an example of low-cost and low-power technology. Through a quantitative techno-economic case study on a realistic network scenario aimed at short-term and medium-term time horizons, the paper provides indications on what could be the impact of the new architecture on costs and energy consumption. The main outcome of the study is that the IT and optical parts are those with the highest fractions of overall cost, and specifically for the optics, the cost of wavelength division multiplexing transceivers increases significantly in the medium term due to the demand for high-capacity connections ($\gt\! 400\;{\rm Gb/s}$), while the line system cost (reconfigurable optical add-drop multiplexer) decreases in percentage. Another significant result is that in terms of energy consumption, the IT component has been found to be the dominant one (70%–75% of the total), followed by packet devices (about 20%–25%) and optical systems, the latter with significantly lower percentage values (less than 5%) in all cases analyzed.

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Network Function	Physical Cores Required	Location
DU	25 core/mob. radio site	LCS/RCS/NCS
CU ( $C P + D P$ )	4.8 core/mob. radio site	RCS/NCS
UPF	1 core/Gb/s traffic	RCS/NCS
AAL wireline	2 core/Gb/s traffic	LCS/RCS/NCS
C&M wireline	0.5 core/OLT mngd.	RCS/NCS
DBNG-U	0.24 core/Gb/s traffic	RCS/NCS
DBNG-C	1 core/DBNG-U VF mngd.	NCS
C&M packet	0.5 core/switch mngd.	RCS/NCS
C&M optical	0.5 core/opt. eq. mngd.	RCS/NCS

System	Cost	Power
ROADM C 2 degrees	5.2	114 W
ROADM CD 4 degrees	12.1	340 W
ROADM CD 8 degrees	21.2	616 W
Telco L3 switch 800 Gb/s	1.7	450 W
Telco L3 switch 1.6 Tb/s	2.5	670 W
Telco L3 switch 3.2 Tb/s	3.3	1000 W
Telco L3 switch 6.4 Tb/s	5.0	1500 W
Telco L3 switch 12.8 Tb/s	6.7	2200 W
Telco L3 switch 25.6 Tb/s	10.0	3250 W
Telco L3 switch 51.2 Tb/s	13.3	4875 W
DC L2 switch 800 Gb/s	0.7	225 W
WDM pluggable 100G metro reach	1	16 W
WDM pluggable 400G metro reach	2	24 W
WDM pluggable 800G metro reach	3.3	32 W
WDM pluggable 1.6T metro reach	5.3	48 W
Pluggable 100G campus reach	0.07	5 W
Pluggable 400G campus reach	0.2	15 W
Pluggable 800G campus reach	0.4	26 W
Pluggable 1.6T campus reach	0.8	40 W
TERIPHIC 400G campus reach	N.A.	10 W
TERIPHIC 800G campus reach	N.A.	16 W
TERIPHIC 1600G campus reach	N.A.	24 W
Server 48 cores	1	500 W
Server 48 cores with accelerators	1.5	750 W
Server 48 cores high storage cap./GPU	1.8	600 W

Short-Term Traffic Scenario
Site Type	TOR–Leaf	Leaf–Spine	WDM Inter-Site
LCS	$8 \times 100 G$	–	$2 \times 100 G$
RCS	$36 \times 100 G$	$16 \times 400 G$	$10 \times 100 G + 2 \times 400 G$
NCS	$66 \times 100 G$	$48 \times 400 G$	$34 \times 400 G$
Medium-Term Traffic Scenario
Site Type	TOR–Leaf	Leaf–Spine	WDM Inter-Site
LCS	$4 \times 400 G$	–	$2 \times 400 G$
RCS	$22 \times 400 G$	$16 \times 800 G$	$10 \times 400 G + 2 \times 1 . 6 T$
NCS	$42 \times 400 G$	$24 \times 1 . 6 T$	$34 \times 1 . 6 T$

Fabric Device	LCS	RCS	NCS
WB switches	1340	10,400	22,950
Conventional transceivers	95	826	1670
TERIPHIC transceivers	75	556	1076

Power Savings	LCS	RCS	NCS
w.r.t. fabric consumption	1.4%	2.4%	2.4%
w.r.t. transceiver consumption	21.1%	32.7%	35.6%

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Journal of Optical Communications and Networking